Low quality lipids such as soyabeanrsoapstock, a by-product of vegetable oil processing can be used as a viable feedstock for the production of biodiesel due to its high yield capacity, availability, and low cost. Sodium hydroxide and methanol were used as catalyst and solvent respectively while n–hexane was added as a co-solvent. Kinetics of the transesterification reaction mechanismfor soyabeansoapstock with and without co-solvent (n-hexane) was carried out using models proposed by Singh & Fernando, (2007) to determine the reaction order and rate constant at different temperatures (45°C, 55°C and 65°C). Similar rate constants were obtained (with and without co-solvent) though with slightly different R2 values showing that n-hexane does not distort the chemistry of the reaction. Negative and very low R2 values obtained at temperatures 45°C and 65°C further affirms 55°C as the optimum temperature for the reaction. An activation energy of 74 KJ/mol and frequency factor of 2.9 was also obtained. Findings from the studyshows that soyabeansoapstock is a viable feedstock for the production of biodiesel and n-hexane was a suitable co-solvent in the transesterification of low quality lipids (soyabean soap stock). A rate constant of 0.0008 min-1 and reaction order of 2 was obtained for the transesterification reaction.
| Published in | Earth Sciences (Volume 10, Issue 5) |
| DOI | 10.11648/j.earth.20211005.11 |
| Page(s) | 198-206 |
| Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
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Copyright © The Author(s), 2021. Published by Science Publishing Group |
Biodiesel, Kinetics, Rate Constant, Soyabeansoapstock
| [1] | Baskar, T., Pravin, R. S., Bagavathi, M., Srinivasan, R & Lin, L (2019). Catalysis in biodiesel production—a review. Clean Energy. 3 (1): pp 2–23. |
| [2] | Choudhury, H. A., Srivastava, P &Moholkar, V. S (2014). Single-step ultrasonic synthesis of biodiesel from crude Jatrophacuraes oil. American Institute of Chemical Engineers Journal. 60: pp 1572-1581. |
| [3] | Darnoko, D & Cheryan, M (2000). Journal of the American Oil Chemists' Society. 77 (12): pp 1263. |
| [4] | Encinar, J. M., Pardal, A & Sanchez, N. (2016). An improvement to the transesterification process by the use of co-solvents to produce biodiesel fuel. 60: pp 1572-1581. |
| [5] | Esonye, C., Onukwuli, O. D & Ofoefule, A. U (2019). Optimization of methyl ester production from Prunus Amygdalus seed oil using response surface methodology and artificial neural networks. Renewable Energy. 130: pp 61-72. |
| [6] | Esonye, C., Onukwuli, O. D & Ofoefule, A. U (2019). Chemical kinetics of a two-step transesterification of dyacrodesedulis seed oil using acid-alkali catalyst. Chemical Engineering Research and Design. 145: pp 245-257. |
| [7] | Faruque, M. O., Razzak, S. A &Hossain, M. M. (2020). Application of heterogenous catalysts for biodiesel production from microalgal oil. Catalysts. 10 (25): pp 1-25. |
| [8] | Furyta, S., Matsuhashi, H., Arata, K. (2004) Catalysis Communications. 5 (721). |
| [9] | Ramadhas, A. S., Jayaraj, S &Muraleedharan, C. (2005). Biodiesel production from high FFA rubber seed oil. Fuel. 84 (4): pp 335–340. |
| [10] | Ganesan, D., Rajendran, A. &Thangavelu, V (2009). An overview on the recent advances in the transesterification of vegetable oils for biodiesel production using chemical and biocatalysts. Rev Environ SciBiotechnol. 8: pp 367. |
| [11] | Hoda, N. (2010). Optimization of biodiesel production from cottonseed oil by transesterification using NaOH and methanol. Energy Sources, Part A: Recovery, Utilization, and Environmental Effects. 32 (5): pp 434-441. |
| [12] | Ling, Gu., Wei, H., Shaokun, T., Songjiang, T & Xiangwen, Z (2015). A novel deep eutectic solvent for biodiesel preparation using a homogenous base catalyst. Chemical Engineering journal. 259: pp 647-652. |
| [13] | Ma, F., Hanna, M. A (1999) Biodiesel production: areview. Bioresour Technol. 70: pp 1–15. |
| [14] | Noureddini, H &Zhu, D. (1997). Kinetics of transesterification of soybean oil. J. Am. Oil Chem. Soc. 74: pp 1457-1463. |
| [15] | Patil, P., Gude, V. G., Pinappu, S & Deng, S (2011). Transesterification kinetics of camelina sativa oil on metal oxide catalysts under conventional and microwave heating conditions. Chemical Engineering Journal. 168: pp 1296–1300. |
| [16] | Permsuwan, A., Tippayawong, N., Tanongkiata, T., Thararux, C &Wangkarn J. (2011). Reaction kinetics of transesterification between palm oil and methanol under subcritical conditions. Energy. Technol. 2: pp 35-42. |
| [17] | Singh, A. K., Fernando, S. D (2007). Reaction Kinetics of Soybean Oil Transesterification Using Heterogeneous Metal Oxide Catalysts. Chem. Eng. Technol. 30 (12): pp 1716–1720. |
| [18] | Vicent, G., Coteron, A., Martinez, M., Aracil, J., (2009) Indusrial Crops and Products. Fuel. 8 (29): pp 88. |
APA Style
Chinedu Gabriel Mbah, Chizoo Esonye, Dominic Okechukwu Onukwuli. (2021). Kinetics of Biodiesel Production from Soya Bean Soap Stock. Earth Sciences, 10(5), 198-206. https://doi.org/10.11648/j.earth.20211005.11
ACS Style
Chinedu Gabriel Mbah; Chizoo Esonye; Dominic Okechukwu Onukwuli. Kinetics of Biodiesel Production from Soya Bean Soap Stock. Earth Sci. 2021, 10(5), 198-206. doi: 10.11648/j.earth.20211005.11
AMA Style
Chinedu Gabriel Mbah, Chizoo Esonye, Dominic Okechukwu Onukwuli. Kinetics of Biodiesel Production from Soya Bean Soap Stock. Earth Sci. 2021;10(5):198-206. doi: 10.11648/j.earth.20211005.11
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Download@article{10.11648/j.earth.20211005.11,
author = {Chinedu Gabriel Mbah and Chizoo Esonye and Dominic Okechukwu Onukwuli},
title = {Kinetics of Biodiesel Production from Soya Bean Soap Stock},
journal = {Earth Sciences},
volume = {10},
number = {5},
pages = {198-206},
doi = {10.11648/j.earth.20211005.11},
url = {https://doi.org/10.11648/j.earth.20211005.11},
eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.earth.20211005.11},
abstract = {Low quality lipids such as soyabeanrsoapstock, a by-product of vegetable oil processing can be used as a viable feedstock for the production of biodiesel due to its high yield capacity, availability, and low cost. Sodium hydroxide and methanol were used as catalyst and solvent respectively while n–hexane was added as a co-solvent. Kinetics of the transesterification reaction mechanismfor soyabeansoapstock with and without co-solvent (n-hexane) was carried out using models proposed by Singh & Fernando, (2007) to determine the reaction order and rate constant at different temperatures (45°C, 55°C and 65°C). Similar rate constants were obtained (with and without co-solvent) though with slightly different R2 values showing that n-hexane does not distort the chemistry of the reaction. Negative and very low R2 values obtained at temperatures 45°C and 65°C further affirms 55°C as the optimum temperature for the reaction. An activation energy of 74 KJ/mol and frequency factor of 2.9 was also obtained. Findings from the studyshows that soyabeansoapstock is a viable feedstock for the production of biodiesel and n-hexane was a suitable co-solvent in the transesterification of low quality lipids (soyabean soap stock). A rate constant of 0.0008 min-1 and reaction order of 2 was obtained for the transesterification reaction.},
year = {2021}
}
TY - JOUR T1 - Kinetics of Biodiesel Production from Soya Bean Soap Stock AU - Chinedu Gabriel Mbah AU - Chizoo Esonye AU - Dominic Okechukwu Onukwuli Y1 - 2021/09/07 PY - 2021 N1 - https://doi.org/10.11648/j.earth.20211005.11 DO - 10.11648/j.earth.20211005.11 T2 - Earth Sciences JF - Earth Sciences JO - Earth Sciences SP - 198 EP - 206 PB - Science Publishing Group SN - 2328-5982 UR - https://doi.org/10.11648/j.earth.20211005.11 AB - Low quality lipids such as soyabeanrsoapstock, a by-product of vegetable oil processing can be used as a viable feedstock for the production of biodiesel due to its high yield capacity, availability, and low cost. Sodium hydroxide and methanol were used as catalyst and solvent respectively while n–hexane was added as a co-solvent. Kinetics of the transesterification reaction mechanismfor soyabeansoapstock with and without co-solvent (n-hexane) was carried out using models proposed by Singh & Fernando, (2007) to determine the reaction order and rate constant at different temperatures (45°C, 55°C and 65°C). Similar rate constants were obtained (with and without co-solvent) though with slightly different R2 values showing that n-hexane does not distort the chemistry of the reaction. Negative and very low R2 values obtained at temperatures 45°C and 65°C further affirms 55°C as the optimum temperature for the reaction. An activation energy of 74 KJ/mol and frequency factor of 2.9 was also obtained. Findings from the studyshows that soyabeansoapstock is a viable feedstock for the production of biodiesel and n-hexane was a suitable co-solvent in the transesterification of low quality lipids (soyabean soap stock). A rate constant of 0.0008 min-1 and reaction order of 2 was obtained for the transesterification reaction. VL - 10 IS - 5 ER -
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